opm-simulators/opm/autodiff/FlowMainSequential.hpp

146 lines
5.9 KiB
C++
Raw Normal View History

Add sequential models for black oil. This commit adds sequential solvers, including a simulator variant using them (flow_sequential.cpp) with an integration test (running SPE1, same as for fully implicit). The sequential code is capable of running several (but not all) test cases without tuning or special parameters, but reducing ds_max a bit (from default 0.2 to say 0.1) helps with transport solver convergence. The Norne model runs fine (esp. with a little tuning). A parameter iterate_to_fully_implicit (defaults to false) is available, when set the simulator will iterate with alternating pressure and transport solves towards the fully implicit solution. Although that takes a lot extra time it serves as a correctness check. Performance is not competitive with fully implicit at this point: essentially both the pressure and transport models inherit the fully implicit model and do a lot of double (or triple) work. The point has been to establish a proof of concept and baseline for further experiments, without disturbing the base model too much (or at all, if possible). Changes to existing code has been minimized by merging most such changes as smaller PRs already, the only remaining such change is to NewtonIterationBlackoilInterleaved. Admittedly, that code (to solve the pressure system with AMG) is not ideal because it duplicates similar code in CPRPreconditioner.hpp and is not parallel. I propose to address this later by refactoring the "solve elliptic system" code from CPRPreconditioner into a separate class that can be used also from here
2015-12-01 07:15:35 -06:00
/*
Copyright 2016 SINTEF ICT, Applied Mathematics.
This file is part of the Open Porous Media project (OPM).
OPM is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OPM is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OPM. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef OPM_FLOWMAINSEQUENTIAL_HEADER_INCLUDED
#define OPM_FLOWMAINSEQUENTIAL_HEADER_INCLUDED
#include <opm/autodiff/FlowMain.hpp>
namespace Opm
{
// The FlowMainSequential class is for a black-oil simulator using the sequential models.
template <class Grid, class Simulator>
class FlowMainSequential : public FlowMainBase<FlowMainSequential<Grid, Simulator>, Grid, Simulator>
{
protected:
using Base = FlowMainBase<FlowMainSequential<Grid, Simulator>, Grid, Simulator>;
using Base::eclipse_state_;
2017-10-29 15:06:19 -05:00
using Base::schedule_;
using Base::summary_config_;
Add sequential models for black oil. This commit adds sequential solvers, including a simulator variant using them (flow_sequential.cpp) with an integration test (running SPE1, same as for fully implicit). The sequential code is capable of running several (but not all) test cases without tuning or special parameters, but reducing ds_max a bit (from default 0.2 to say 0.1) helps with transport solver convergence. The Norne model runs fine (esp. with a little tuning). A parameter iterate_to_fully_implicit (defaults to false) is available, when set the simulator will iterate with alternating pressure and transport solves towards the fully implicit solution. Although that takes a lot extra time it serves as a correctness check. Performance is not competitive with fully implicit at this point: essentially both the pressure and transport models inherit the fully implicit model and do a lot of double (or triple) work. The point has been to establish a proof of concept and baseline for further experiments, without disturbing the base model too much (or at all, if possible). Changes to existing code has been minimized by merging most such changes as smaller PRs already, the only remaining such change is to NewtonIterationBlackoilInterleaved. Admittedly, that code (to solve the pressure system with AMG) is not ideal because it duplicates similar code in CPRPreconditioner.hpp and is not parallel. I propose to address this later by refactoring the "solve elliptic system" code from CPRPreconditioner into a separate class that can be used also from here
2015-12-01 07:15:35 -06:00
using Base::param_;
using Base::fis_solver_;
using Base::parallel_information_;
friend Base;
// ------------ Methods ------------
// Print startup message if on output rank.
void printStartupMessage()
{
if (Base::output_cout_) {
const std::string version = moduleVersionName();
std::cout << "**********************************************************************\n";
std::cout << "* *\n";
std::cout << "* This is Flow-Sequential (version " << version << ")"
<< std::string(17 - version.size(), ' ') << "*\n";
std::cout << "* *\n";
std::cout << "* Flow-Sequential is a simulator for fully implicit three-phase, *\n";
std::cout << "* black-oil flow, and is part of OPM. *\n";
std::cout << "* For more information see https://opm-project.org *\n";
Add sequential models for black oil. This commit adds sequential solvers, including a simulator variant using them (flow_sequential.cpp) with an integration test (running SPE1, same as for fully implicit). The sequential code is capable of running several (but not all) test cases without tuning or special parameters, but reducing ds_max a bit (from default 0.2 to say 0.1) helps with transport solver convergence. The Norne model runs fine (esp. with a little tuning). A parameter iterate_to_fully_implicit (defaults to false) is available, when set the simulator will iterate with alternating pressure and transport solves towards the fully implicit solution. Although that takes a lot extra time it serves as a correctness check. Performance is not competitive with fully implicit at this point: essentially both the pressure and transport models inherit the fully implicit model and do a lot of double (or triple) work. The point has been to establish a proof of concept and baseline for further experiments, without disturbing the base model too much (or at all, if possible). Changes to existing code has been minimized by merging most such changes as smaller PRs already, the only remaining such change is to NewtonIterationBlackoilInterleaved. Admittedly, that code (to solve the pressure system with AMG) is not ideal because it duplicates similar code in CPRPreconditioner.hpp and is not parallel. I propose to address this later by refactoring the "solve elliptic system" code from CPRPreconditioner into a separate class that can be used also from here
2015-12-01 07:15:35 -06:00
std::cout << "* *\n";
std::cout << "**********************************************************************\n\n";
}
}
// Setup linear solver.
// Writes to:
// fis_solver_
// param_ (conditionally)
// The CPR solver cannot be used with the sequential model.
// Also, the interleaved solver requires the full sparsity pattern option.
void setupLinearSolver()
{
const std::string cprSolver = "cpr";
const std::string interleavedSolver = "interleaved";
const std::string directSolver = "direct";
std::string flowDefaultSolver = interleavedSolver;
if (!param_.has("solver_approach")) {
if (eclipse_state_->getSimulationConfig().useCPR()) {
Add sequential models for black oil. This commit adds sequential solvers, including a simulator variant using them (flow_sequential.cpp) with an integration test (running SPE1, same as for fully implicit). The sequential code is capable of running several (but not all) test cases without tuning or special parameters, but reducing ds_max a bit (from default 0.2 to say 0.1) helps with transport solver convergence. The Norne model runs fine (esp. with a little tuning). A parameter iterate_to_fully_implicit (defaults to false) is available, when set the simulator will iterate with alternating pressure and transport solves towards the fully implicit solution. Although that takes a lot extra time it serves as a correctness check. Performance is not competitive with fully implicit at this point: essentially both the pressure and transport models inherit the fully implicit model and do a lot of double (or triple) work. The point has been to establish a proof of concept and baseline for further experiments, without disturbing the base model too much (or at all, if possible). Changes to existing code has been minimized by merging most such changes as smaller PRs already, the only remaining such change is to NewtonIterationBlackoilInterleaved. Admittedly, that code (to solve the pressure system with AMG) is not ideal because it duplicates similar code in CPRPreconditioner.hpp and is not parallel. I propose to address this later by refactoring the "solve elliptic system" code from CPRPreconditioner into a separate class that can be used also from here
2015-12-01 07:15:35 -06:00
flowDefaultSolver = cprSolver;
}
}
const std::string solver_approach = param_.getDefault("solver_approach", flowDefaultSolver);
if (solver_approach == cprSolver) {
OPM_THROW( std::runtime_error , "CPR solver is not ready for use with sequential simulator.");
} else if (solver_approach == interleavedSolver) {
if (!param_.has("require_full_sparsity_pattern")) {
param_.insertParameter("require_full_sparsity_pattern", "true");
}
fis_solver_.reset(new NewtonIterationBlackoilInterleaved(param_, parallel_information_));
} else if (solver_approach == directSolver) {
fis_solver_.reset(new NewtonIterationBlackoilSimple(param_, parallel_information_));
} else {
OPM_THROW( std::runtime_error , "Internal error - solver approach " << solver_approach << " not recognized.");
}
}
// Create simulator instance.
// Writes to:
// simulator_
void createSimulator()
{
// We must override the min_iter argument unless it was already supplied, to avoid requiring iteration.
if (!param_.has("min_iter")) {
param_.insertParameter("min_iter", "0");
}
// Create the simulator instance.
Base::simulator_.reset(new Simulator(Base::param_,
Base::grid_init_->grid(),
*Base::geoprops_,
*Base::fluidprops_,
Base::rock_comp_->isActive() ? Base::rock_comp_.get() : nullptr,
*Base::fis_solver_,
Base::gravity_.data(),
Base::deck_->hasKeyword("DISGAS"),
Base::deck_->hasKeyword("VAPOIL"),
Base::eclipse_state_,
2017-10-29 15:06:19 -05:00
Base::schedule_,
Base::summary_config_,
Add sequential models for black oil. This commit adds sequential solvers, including a simulator variant using them (flow_sequential.cpp) with an integration test (running SPE1, same as for fully implicit). The sequential code is capable of running several (but not all) test cases without tuning or special parameters, but reducing ds_max a bit (from default 0.2 to say 0.1) helps with transport solver convergence. The Norne model runs fine (esp. with a little tuning). A parameter iterate_to_fully_implicit (defaults to false) is available, when set the simulator will iterate with alternating pressure and transport solves towards the fully implicit solution. Although that takes a lot extra time it serves as a correctness check. Performance is not competitive with fully implicit at this point: essentially both the pressure and transport models inherit the fully implicit model and do a lot of double (or triple) work. The point has been to establish a proof of concept and baseline for further experiments, without disturbing the base model too much (or at all, if possible). Changes to existing code has been minimized by merging most such changes as smaller PRs already, the only remaining such change is to NewtonIterationBlackoilInterleaved. Admittedly, that code (to solve the pressure system with AMG) is not ideal because it duplicates similar code in CPRPreconditioner.hpp and is not parallel. I propose to address this later by refactoring the "solve elliptic system" code from CPRPreconditioner into a separate class that can be used also from here
2015-12-01 07:15:35 -06:00
*Base::output_writer_,
Base::threshold_pressures_));
}
};
} // namespace Opm
#endif // OPM_FLOWMAINSEQUENTIAL_HEADER_INCLUDED